Method and apparatus for post exposure processing of photoresist wafers

ABSTRACT

Embodiments described herein relate to methods and apparatus for performing immersion field guided post exposure bake processes. Embodiments of apparatus described herein include a chamber body defining a processing volume. A pedestal may be disposed within the processing volume and a first electrode may be coupled to the pedestal. A moveable stem may extend through the chamber body opposite the pedestal and a second electrode may be coupled to the moveable stem. In certain embodiments, a fluid containment ring may be coupled to the pedestal and a dielectric containment ring may be coupled to the second electrode.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims benefit to U.S. Provisional Patent ApplicationNo. 62/261,171, filed Nov. 30, 2015, and U.S. Provisional PatentApplication No. 62/267,531, filed Dec. 15, 2015, both of which arehereby incorporated by reference in their entirety.

BACKGROUND Field

The present disclosure generally relates to methods and apparatus forprocessing a substrate, and more specifically to methods and apparatusfor improving photolithography processes.

Description of the Related Art

Integrated circuits have evolved into complex devices that can includemillions of components (e.g., transistors, capacitors and resistors) ona single chip. Photolithography is a process that may be used to formcomponents on a chip. Generally the process of photolithography involvesa few basic stages. Initially, a photoresist layer is formed on asubstrate. A chemically amplified photoresist may include a resist resinand a photoacid generator. The photoacid generator, upon exposure toelectromagnetic radiation in the subsequent exposure stage, alters thesolubility of the photoresist in the development process. Theelectromagnetic radiation may have any suitable wavelength, for example,a 193 nm ArF laser, an electron beam, an ion beam, or other suitablesource.

In an exposure stage, a photomask or reticle may be used to selectivelyexpose certain regions of the substrate to electromagnetic radiation.Other exposure methods may be maskless exposure methods. Exposure tolight may decompose the photo acid generator, which generates acid andresults in a latent acid image in the resist resin. After exposure, thesubstrate may be heated in a post-exposure bake process. During thepost-exposure bake process, the acid generated by the photoacidgenerator reacts with the resist resin, changing the solubility of theresist during the subsequent development process.

After the post-exposure bake, the substrate, particularly thephotoresist layer, may be developed and rinsed. Depending on the type ofphotoresist used, regions of the substrate that were exposed toelectromagnetic radiation may either be resistant to removal or moreprone to removal. After development and rinsing, the pattern of the maskis transferred to the substrate using a wet or dry etch process.

The evolution of chip design continually requires faster circuitry andgreater circuit density. The demands for greater circuit densitynecessitate a reduction in the dimensions of the integrated circuitcomponents. As the dimensions of the integrated circuit components arereduced, more elements are required to be placed in a given area on asemiconductor integrated circuit. Accordingly, the lithography processmust transfer even smaller features onto a substrate, and lithographymust do so precisely, accurately, and without damage. In order toprecisely and accurately transfer features onto a substrate, highresolution lithography may use a light source that provides radiation atsmall wavelengths. Small wavelengths help to reduce the minimumprintable size on a substrate or wafer. However, small wavelengthlithography suffers from problems, such as low throughput, increasedline edge roughness, and/or decreased resist sensitivity.

In a recent development, an electrode assembly is utilized to generatean electric field to a photoresist layer disposed on the substrate priorto or after an exposure process so as to modify chemical properties of aportion of the photoresist layer where the electromagnetic radiation istransmitted to for improving lithography exposure/developmentresolution. However, the challenges in implementing such systems havenot been overcome.

Therefore, there is a need for improved methods and apparatus forimproving photolithography processes.

SUMMARY

In one embodiment, a substrate processing apparatus is provided. Theapparatus includes a chamber body defining a processing volume and apedestal disposed within the processing volume. One or more fluidsources may be coupled to the processing volume through the pedestal anda drain may be coupled to the processing volume through the pedestal. Afirst electrode is coupled to the pedestal and a fluid containment ringis coupled to the pedestal radially outward of the first electrode. Amoveable stem may be disposed opposite the pedestal and extend throughthe chamber body, and a second electrode may be coupled to the stem.

In another embodiment, a substrate processing apparatus is provided. Theapparatus includes a chamber body defining a processing volume and apedestal is disposed in the processing volume. A drain may be coupled tothe processing volume through the pedestal, a first electrode may becoupled to the pedestal, and a fluid containment ring may be coupled tothe pedestal radially outward of the first electrode. A moveable stemmay be disposed opposite the pedestal and extend through the chamberbody. A second electrode may be coupled to the stem and a dielectriccontainment ring may be coupled to the second electrode. One or morefluid sources may be coupled to the processing volume through thedielectric containment ring.

In yet another embodiment, a substrate processing apparatus is provided.The apparatus includes a chamber body defining a processing volume, apedestal may be disposed in the processing volume, and a first electrodemay be coupled to the pedestal. A moveable stem may be disposed oppositethe pedestal and extend through the chamber body. A second electrode maybe coupled to the stem and a dielectric containment ring may be coupledto the second electrode. An elastomeric O-ring may be coupled to thedielectric containment ring opposite the second electrode. One or morefluid sources, a drain, and a purge gas source may each be coupled tothe processing volume through the dielectric containment ring.

BRIEF DESCRIPTION OF THE DRAWINGS

So that the manner in which the above recited features of the presentdisclosure can be understood in detail, a more particular description ofthe disclosure, briefly summarized above, may be had by reference toembodiments, some of which are illustrated in the appended drawings. Itis to be noted, however, that the appended drawings illustrate onlyexemplary embodiments and are therefore not to be considered limiting ofits scope, may admit to other equally effective embodiments.

FIG. 1 schematically illustrates a cross-sectional view of an immersionfield guided post exposure bake chamber according to one embodimentdescribed herein.

FIG. 2 schematically illustrates a cross-sectional view of the chamberof FIG. 1 in a processing position according to one embodiment describedherein.

FIG. 3 schematically illustrates a cross-sectional view of an immersionfield guided post exposure bake chamber according to one embodimentdescribed herein.

FIG. 4 schematically illustrates a cross-sectional view of an immersionfield guided post exposure bake chamber according to one embodimentdescribed herein.

FIG. 5 schematically illustrates a cross-sectional view of an immersionfield guided post exposure bake chamber according to one embodimentdescribed herein.

FIG. 6 schematically illustrates a cross-sectional view of the chamberof FIG. 5 in a processing position according to one embodiment describedherein.

FIG. 7 schematically illustrates a cross-sectional view of an immersionfield guided post exposure bake chamber according to one embodimentdescribed herein.

FIG. 8 schematically illustrates a cross-sectional view of an immersionfield guided post exposure bake chamber according to one embodimentdescribed herein.

FIG. 9 illustrates operations of a method for performing an immersionpost exposure bake process according to one embodiment described herein.

To facilitate understanding, identical reference numerals have beenused, where possible, to designate identical elements that are common tothe figures. It is contemplated that elements and features of oneembodiment may be beneficially incorporated in other embodiments withoutfurther recitation.

DETAILED DESCRIPTION

FIG. 1 schematically illustrates a cross-sectional view of a processingchamber 100 according to one embodiment described herein. The processingchamber 100 includes a chamber body 102 which defines a processingvolume 104. A pump 172 may be fluidly coupled to the processing volume104 through the chamber body 102 and may be configured to generate avacuum within the processing volume 104 or exhaust fluids and othermaterials from the processing volume 104. A slit valve 148 may be formedin the chamber body 102 to provide for ingress and egress of a substratefor processing. A slit valve door 150 may be coupled to the chamber body102 adjacent the slit valve 148. Generally, the chamber body 102 may beformed from materials suitable for performing immersion field guidedpost exposure bake (iFGPEB) processes therein, such as aluminum,stainless steel, and alloys thereof. The chamber body 102 may also beformed from various other materials such as polymers, for example,polytetrafluoroethylene (PTFE), or high temperature plastics, such aspolyether ether ketone (PEEK).

A pedestal 106 may be disposed in the processing volume 104 and may becoupled to the chamber body 102. In one embodiment, the pedestal 106 maybe fixably coupled to the chamber body 102. In another embodiment, thepedestal 106 may be rotatably coupled to the chamber body 102. In thisembodiment, a motor (not shown) may be coupled to the pedestal 106 andthe motor may be configured to impart rotational movement to thepedestal 106. It is contemplated that rotation of the pedestal 106 maybe utilized to spin dry substrates after processing of the substrates.

A first electrode 108 may be coupled to the pedestal 106. The firstelectrode 108 may be fixably coupled to the pedestal 106 or may berotatably coupled to the pedestal 106. In embodiments where the firstelectrode 108 is rotatably coupled to the pedestal 106, the rotation ofthe first electrode 108 may be utilized to spin dry substrates afterprocessing. The first electrode 108 may be formed from an electricallyconductive metallic material. In addition, the material utilized for thefirst electrode 108 may be a non-oxidative material. The materialsselected for the first electrode 108 may provide for desirable currentuniformity and low resistance across the surface of the first electrode108. In certain embodiments, the first electrode 108 may be a segmentedelectrode configured to introduce voltage non-uniformities across thesurface of the first electrode 108. In this embodiment, a plurality ofpower sources may be utilized to power different segments of the firstelectrode 108.

A fluid containment ring 112 may be coupled to the pedestal 106 radiallyoutward from the first electrode 108. The fluid containment ring 112 maybe manufactured from a non-conductive material, such as a ceramicmaterial or a high temperature plastic material. The pedestal 106 andthe fluid containment ring 112 may have a substantially similar diameterand a distance radially inward from the fluid containment ring 112 tothe first electrode 108 may be between about 0.1 cm and about 3.0 cm,such as between about 0.5 cm and about 2.0 cm, for example, about 1.0cm. The fluid containment ring 112 may extend from the pedestal 106 tofurther define the processing volume 104. Generally, a top of the fluidcontainment ring 112 may be co-planar with or disposed below a planeoccupied by the slit valve 148.

The pedestal 106 may include one or more conduits disposed therethroughand an integrally disposed heating apparatus (not shown) may be disposedwithin the pedestal 106 to preheat fluids traveling through theconduits. A process fluid source 116 may be fluidly coupled to theprocessing volume 104 via a conduit 114. The conduit 114 may extend fromthe process fluid source 116 through the chamber body 102 and thepedestal 106 to the processing volume 104. In one embodiment, a fluidoutlet 124 may be formed in the pedestal 106 radially outward from thefirst electrode 108 and radially inward from the fluid containment ring112. A valve 118 may be disposed on the conduit 114 between the fluidoutlet 124 and the process fluid source 116. A rinse fluid source 120may also be fluidly coupled to the processing volume 104 via the fluidconduit 114. A valve 122 may be disposed on the conduit 114 between thefluid outlet 124 and the rinse fluid source 120. The process fluidsource 116 may be configured to deliver fluids utilized duringapplication of an electrical field during an iFGPDB process. The rinsefluid source 120 may be configured to deliver fluids to rinse substratesafter an iFGPEB process has been performed.

A drain 128 may be fluidly coupled to the processing volume 104 via aconduit 126. The conduit 126 may extend from the drain 128 through thechamber body 102 and the pedestal 106. In one embodiment, a fluid inlet132 may be formed in the pedestal 106 radially outward from the firstelectrode 108 and radially inward from the fluid containment ring 112. Avalve 130 may be disposed on the conduit 126 between the fluid inlet 132and the drain 128. Fluids, such as fluid from the process fluid source116 and the rinse fluid source 120, may be removed from the processingvolume 104 via the fluid inlet 132 and drain 128.

A vacuum source 136 may be coupled via a conduit 134 to a top surface ofthe first electrode 108. The conduit 134 may extend through the chamberbody 102, the pedestal 106, and the first electrode 108. As illustrated,a substrate 110 may be disposed on the first electrode 108. The conduit134 may be positioned underneath a region covered by the substrate 110when the substrate 110 is positioned on the first electrode 108. Thevacuum source 136 may be configured to draw a vacuum to secure thesubstrate 110 to the first electrode 108. In certain embodiment, thevacuum source 136 and the conduit 134 may be optional if the substratesecured on the first electrode 108 by other means, such as electrostaticchucking or mechanical apparatus (i.e. rings, pins, etc.)

A heat source 140 may be electrically coupled to the first electrode 108via a conduit 138. The heat source 140 may provide power to one or moreheating elements, such as resistive heaters, disposed within the firstelectrode 108. It is also contemplated that the heat source 140 mayprovide power to heating elements disposed within the pedestal 106. Theheat source 140 is generally configured to heat either the firstelectrode 108 and/or the pedestal 106 to facilitate preheating of fluidduring iFGPEB processes. In one embodiment, the heat source 140 may beconfigured to heat the first electrode 108 to a temperature of betweenabout 70° C. and about 130° C., such as about 110° C. In otherembodiments, the heat source may be coupled to the conduits 114 topreheat fluids entering the processing volume 104 from the process fluidsource 116 and/or the rinse fluid source 120. A temperature sensingapparatus 142 may also be coupled to the first electrode 108 via theconduit 138. The temperature sensing apparatus 142, such as athermocouple or the like, may be communicatively coupled to the heatsource 140 to provide temperature feedback and facilitate heating of thefirst electrode 108.

A power source 144 is also coupled to the first electrode 108 via theconduit 138. The power source 144 may be configured to supply, forexample, between about 1 V and about 20 kV to the first electrode.Depending on the type of process fluid utilized, current generated bythe power source 144 may be on the order of tens of nano-amps tohundreds of milliamps. In one embodiment, the power source 144 may beconfigured to generate electric fields ranging from about 1 kV/m toabout 2 MeV/m. In some embodiments, the power source 144 may beconfigured to operate in either voltage controlled or current controlledmodes. In both modes, the power source may output AC, DC, and/or pulsedDC waveforms. Square or sine waves may be utilized if desired. The powersource 144 may be configured to provide power at a frequency of betweenabout 0.1 Hz and about 1 MHz, such as about 5 kHz. The duty cycle of thepulsed DC power or AC power may be between about 5% and about 95%, suchas between about 20% and about 60%.

The rise and fall time of the pulsed DC power or AC power may be betweenabout 1 ns and about 1000 ns, such as between about 10 ns and about 500ns. A sensing apparatus 146 may also be coupled to the first electrode108 via the conduit 138. The sensing apparatus 146, such as a voltmeteror the like, may be communicatively coupled to the power source 144 toprovide electrical feedback and facilitate control of the power appliedto the first electrode 108. The sensing apparatus 146 may also beconfigured to sense a current applied to the first electrode 108 via thepower source 144.

A moveable stem 152 may be disposed through the chamber body 102opposite the pedestal 106. The stem 152 is configured to move in the Zdirection (i.e. towards and away from the pedestal 106) and may be movedbetween a non-processing position as shown and a processing position(illustrated in FIG. 2). A second electrode 154 may be coupled to thestem 152. The second electrode 154 may be formed from the same materialsas the first electrode 108. Similar to the first electrode 108, thesecond electrode 154 may be segmented in certain embodiments.

A purge gas source 158 may be fluidly coupled to the processing volume104 via a conduit 156. The conduit 156 may extend from the purge gassource 158 through the stem 152 and the second electrode 154. In certainembodiments, the conduit 156 may be formed from a flexible material toaccommodate movement of the stem 152. Although not illustrated, in analternative embodiment, the conduit may extend through the stem 152 tothe processing volume 104 and not the second electrode 154. A valve 160may be disposed on the conduit 156 between the stem 152 and the purgegas source 158. Gases provided by the purge gas source 158 may includenitrogen, hydrogen, inert gases and the like to purge the processingvolume 104 during or after iFGPEB processing. When desired, purge gasesmay be exhausted from the processing volume 104 via the pump 172.

A heat source 170, temperature sensing apparatus 168, a power source166, and a sensing apparatus 164 may be communicatively coupled to thesecond electrode 154 via a conduit 162. The heat source 170, thetemperature sensing apparatus 168, the power source 166, and the sensingapparatus 164 may be configured similarly to the heat source 140, thetemperature sensing apparatus 142, the power source 144, and the sensingapparatus 146.

The embodiments described herein relate to methods as well as theapparatus for performing immersion field guided post exposure bakeprocesses. The methods and apparatuses disclosed herein may increase thephotoresist sensitivity and productivity of photolithography processes.The random diffusion of acids generated by a photoacid generator duringa post-exposure bake procedure contributes to line edge/width roughnessand reduced resist sensitivity. An electrode assembly may be utilized toapply an electric field to the photoresist layer during photolithographyprocesses. The field application may control the diffusion of thecharged species generated by the photoacid generator.

An air gap defined between the photoresist layer and the electrodeassembly may result in voltage drop applied to the electrode assembly,thus, adversely lowering the level of the electric field desired to begenerated to the photoresist layer. As a result of the voltage drop,levels of the electric field at the photoresist layer may result ininsufficient or inaccurate voltage power to drive or create chargedspecies in the photoresist layer in certain desired directions. Thus,diminished line edge profile control to the photoresist layer mayprevalent.

An intermediate medium may be disposed between the photoresist layer andthe electrode assembly to prevent the air gap from being created so asto maintain the level of the electric field interacting with thephotoresist layer at a certain desired level. By doing so, the chargedspecies generated by the electric field may be guided in a desireddirection along the line and spacing direction, preventing the lineedge/width roughness that results from inaccurate and random diffusion.Accordingly, a controlled or desired level of electric field asgenerated may increase the accuracy and sensitivity of the photoresistlayer to exposure and/or development process. In one example, theintermediate medium may be non-gas phase medium, such as a slurry, gel,or liquid solution that may efficiently maintain voltage level asapplied at a determined range when transmitting from the electrodeassembly to the photoresist layer disposed on the substrate. Chargesgenerated by the electric field may be transferred between theintermediate medium and the photoresist which may result in a netcurrent flow. In certain embodiments, the net current flow may improvereactions characteristics, such as improving the reaction rate of thephotoresist. Operating the power source 144 in a current controlled modealso advantageously enables control of the amount of charges that aretransferred between the intermediate medium and the photoresist.

FIG. 2 schematically illustrates a cross-sectional view of the chamber100 of FIG. 1 in a processing position according to one embodimentdescribed herein. The stem 152 may be moved toward the pedestal 106 intoa processing position. In the processing position, a distance 174between the second electrode 154 and the substrate 110 may be betweenabout 1 mm and about 1 cm, such as about 2 mm. Processing fluid may bedelivered to the processing volume 104 defined and retained by the fluidcontainment ring 112 and the second electrode 154 may be partially orcompletely submerged when the stem 152 is located in the processingposition. Power may be applied to one or both of the electrodes 108, 154to perform an iFGPEB process

In some embodiments, the first electrode 108 and the second electrode154 are configured to generate an electric field parallel to the x-yplane defined by the substrate 110. For example, the electrodes 108, 154may be configured to generate an electric field in one of the ydirection, x direction or other direction in the x-y plane. In oneembodiment, the electrodes 108, 154 are configured to generate anelectric field in the x-y plane and in the direction of latent imagelines, which may be patterned on the substrate 110. In anotherembodiment, the electrodes 108, 154 are configured to generate anelectric field in the x-y plane and perpendicular to the direction oflatent image lines patterned on the substrate 110. The electrodes 108,154 may additionally or alternatively be configured to generate anelectric field in the z-direction, such as, for example, perpendicularto the substrate 110.

FIG. 3 schematically illustrates a cross-sectional view of an iFGPEBchamber 300 according to one embodiment described herein. A thirdelectrode 302 may be similar to the second electrode 154 in certainaspects. A dielectric containment ring 304 may be coupled to the thirdelectrode 302 opposite the stem 152. The dielectric containment ring 304may have a diameter similar to the diameter of the third electrode 302.The dielectric containment ring 304 may be formed from a dielectricmaterial, such as polymers or ceramics with suitable dielectricproperties. An O-ring 308 may be coupled to the dielectric containmentring 304 opposite the third electrode 302 and extend circumferentiallyabout the dielectric containment ring 304. The O-ring 308 may be formedfrom an elastomeric material, such as a polymer and may be compressiblewhen the stem 152 is disposed in a processing position.

For example, when the stem 152 is disposed in the processing position(illustrated in FIG. 2) the O-ring 308 may contact a region 310 of thefirst electrode 108 or a region 312 of the pedestal 106. The diameter ofthe third electrode 302 and the diameter of the dielectric containmentring 304 may be selected depending on the desired region 310, 312 ofcontact by the O-ring 308. It is contemplated that when the O-ring 308,and third electrode 302/dielectric containment ring 304 are configuredto contact the region 312 on the pedestal 106, the point of contact bythe O-ring 308 may be radially inward from the fluid inlet 132 toprovide for unrestricted fluid access to the drain 128. The O-ring 308,when the stem 152 is disposed in the processing position, may also besized and positioned to contact an exclusion zone of the substrate 110.Generally, the exclusion zone of the substrate 110 is a region of thesubstrate 110 radially inward a distance of about 1 mm to about 3 mmfrom the circumference of the substrate 110. In this embodiment, theprocessing volume 104 may be defined by the substrate 110, thedielectric containment ring 304, and the third electrode 302.Advantageously, a backside of the substrate 110 coupled to the firstelectrode 108 may remain unexposed to process or rinse fluids which aidsin preventing fluid from entering the vacuum source 136.

The rinse fluid source 120 may be fluidly coupled with the processingvolume 104 via the conduit 156 which may extend through the stem 152,the third electrode 302 and the dielectric containment ring 304. A fluidoutlet 306 of the conduit 156 may be disposed at an inner diameter ofthe dielectric containment ring 304. The rinse fluid source 120 and thepurge gas source 158 may also be coupled to the conduit 156.Alternatively, the fluid conduit 156 may extend through the stem 152above the third electrode 302 and extend radially outward of the thirdelectrode 302 through the dielectric containment ring 304 to the fluidoutlet 306.

FIG. 4 schematically illustrates a cross-sectional view of an iFGPEBchamber 400 according to one embodiment described herein. The chamber400 is similar to the chamber 300 in certain aspects, however, the fluidcontainment ring 112 is not coupled to the pedestal 106. An exhaust 418may be fluidly coupled to the processing volume 104 via a conduit 414which may extend through the stem 152, a fourth electrode 402 (which iscoupled to the stem 152), and a dielectric containment ring 404. Incertain embodiments, the conduit 414 may be formed from a flexiblematerial to accommodate movement of the stem 152. A fluid outlet 416 ofthe conduit 414 may be disposed at an inner diameter of the dielectriccontainment ring 404. A valve may be disposed on the conduit 414 betweenthe exhaust 418 and the stem 152. Alternatively, the conduit 414 mayextend through the stem 152 above the fourth electrode 402 and extendradially outward of the fourth electrode 402 through the dielectriccontainment ring 404 to the fluid outlet 416.

Similar to the chamber 300, when the stem 152 is disposed in aprocessing position (illustrated in FIG. 2), the fourth electrode 402,the dielectric containment ring 404, and an O-ring 408 coupledcircumferentially about the dielectric containment ring 404 opposite thefourth electrode 402, may be sized such that the O-ring 408 contactseither the region 410 on the first electrode 108 or the region 412 ofthe pedestal 106. During processing, various process and rinse fluid maybe introduced to the processing volume 104 which is further defined bythe dielectric containment ring 404 and the fourth electrode 402. Thefluids may be exhausted from the processing volume 104 via the fluidoutlet 416 to the exhaust 418.

Although not shown in FIGS. 1-4, lift pins may extend through thepedestal 106 and/or first electrode 108 to facilitate positioning of thesubstrate 110 on the first electrode 108. For example, when the stem 152is in a non-processing raised position, the lift pins may extend upwardand receive a substrate from a robot blade extending through the slitvalve 148. The lift pins may then retract and position the substrate 110on the first electrode 108.

FIG. 5 schematically illustrates a cross-sectional view of an iFGPEBchamber 500 according to one embodiment described herein. The chamber500 includes a chamber body 502 defining a processing volume 504, apedestal 506, a first electrode 508, and a fluid containment ring 512which may be similar in certain aspects to the chamber body 102, theprocessing volume 104, the pedestal 106, the first electrode 108, andthe fluid containment ring 112, except that the components of thechamber 500 are sized to accommodate a rotational stem 516 and a secondelectrode 518 coupled to the rotational stem 516. The rotational stem516 may be rotatably coupled to a bearing member 514. The bearing member514 may be coupled to the chamber body 502 such that the bearing member514 rotates about an X or Y (horizontal) axis.

The substrate 110 may be disposed on the second electrode 518 in thenon-processing position illustrated in FIG. 5. FIG. 6 illustrates thechamber 500 of FIG. 5 in a processing position. The rotatable stem 516,having received the substrate 110 on the second electrode 518, mayrotate about the horizontal axis to the processing position asillustrated. Fluid supplied to the processing volume 504 further definedby the fluid containment ring 512 may be in an amount suitable topartially or entirely submerge the second electrode 518. An iFGPEBprocess may be performed and the rotatable stem 516 may rotate back tothe non-processing position. The bearing member 514 may also beconfigured to rotate about the Z axis (vertical) to spin the rotatablestem 516 and second electrode 518 to expel fluid remaining on thesubstrate 110.

FIG. 7 schematically illustrates a cross-sectional view of an immersionfield guided post exposure bake chamber 700 according to one embodimentdescribed herein. The chamber 700 includes a chamber body 702, which maybe manufactured from a metallic material, such as aluminum, stainlesssteel, and alloys thereof. The chamber body 702 may also be formed fromvarious other materials such as polymers, for example,polytetrafluoroethylene (PTFE), or high temperature plastics, such aspolyether ether ketone (PEEK). The body 702 includes a fluid containmentring 712 which may extend from the body 702 and at least partiallydefine a first processing volume 704. The body 702 may also includesidewalls 794 and a lid 796 which extends from the sidewalls 794. Thebody 702, the fluid containment ring 712, the sidewalls 794, and the lid796 may define a second processing volume 754 which is formed radiallyoutward from the first processing volume 704. An opening 792 may bedefined by the lid 796 and the opening 792 may be sized to accommodatepassage of a substrate 710 therethrough.

A door 706 may be operably coupled to the chamber body 702 and disposedadjacent the lid 796. The door 706 may be formed from materials similarto materials selected for the chamber body 702 and a shaft 798 mayextend through the door 706. Alternatively, the chamber body 702 may beformed from a first material, such as a polymer, and the door 706 may beformed from a second material, such as a metallic material. The door 706may be coupled to a track (not shown) and the door may be configured totranslate along the track in the X-axis. A motor (not shown) may becoupled to the door and/or the track to facilitate movement of the door706 along the X-axis. Although the door 706 is illustrated in aprocessing position, the door 706 may be configured to rotate about theshaft 798 around the Z-axis. Prior to rotating, the door 706 may moveaway from the chamber body 702 along the X-axis and clear the lid 796prior to rotating. For example, the door 706 may rotate about 90° fromthe illustrated processing position to a loading position where thesubstrate 710 may be loaded and unloaded from a first electrode 708coupled to the door 706.

The first electrode 708, which may be similar to the first electrode108, is sized to accommodate attachment of the substrate 710 thereon.The first electrode 708 may also be sized to allow for passage throughthe opening 792 defined by the lid 796. In one embodiment, the firstelectrode 708 may be fixably coupled to the door 706. In anotherembodiment, the first electrode 708 may be rotatably coupled to the door706. In this embodiment, a motor 772 may be coupled to the door 706opposite the first electrode 708 and the motor 772 may be configured torotate the first electrode 708 about the X-axis. Rotation of the firstelectrode 708 may be utilized to spin dry the substrate 710 after iFGPEBprocessing. To perform spin drying, the door 706 may translate along theX-axis away from the fluid containment ring 712 such that the substrate710 has not passed through the opening 792. The motor 772 may beactivated to spin the first electrode 708 (with the substrate 710chucked to the first electrode) to remove fluids from surfaces of thesubstrate 710.

A vacuum source 736 may be in fluid communication with a substratereceiving surface of the first electrode 708. The vacuum source 736 maybe coupled to a conduit 734 which extends from the vacuum source 736through the door 706 and the first electrode 708. Generally, the vacuumsource 736 is configured to vacuum chuck the substrate 710 to the firstelectrode 708. A heat source 764, a temperature sensing apparatus 766, apower source 768, and a sensing apparatus 770 may also be coupled to thefirst electrode 708 via a conduit 762. The heat source 764, thetemperature sensing apparatus 766, the power source 768, and the sensingapparatus 770 may be similarly configured to the heat source 140, thetemperature sensing apparatus 142, the power source 144, and the sensingapparatus 146 described in greater detail with regard to FIG. 1.

A second electrode 750 may be coupled to the chamber body 702. The fluidcontainment ring 712 may surround the second electrode 750 such that thefirst processing volume 704 is defined (when the door 706 is in theprocessing position) by the second electrode 750, the fluid containmentring 712, and the substrate 710. An O-ring 752 may be coupled to thefluid containment ring 712 and the O-ring 752 may be formed from anelastomeric material, such as a polymer or the like. A circumferencedefined by the O-ring 752 may be sized to contact an exclusion zone ofthe substrate 710 when the substrate 710 is in the processing positionas illustrated. The O-ring 752 may also be sized to contact an edge ofthe substrate 710. By contacting the substrate 710, it is contemplatedthat the O-ring 752 may prevent fluid from escaping the first processingvolume 704 and reduce or eliminate the possibility of fluid entering thevacuum source 736.

A process fluid source 716 may fluidly coupled to the first processingvolume 704 via a conduit 714. The conduit 714 may extend from theprocess fluid source 716 through the chamber body 702 and the fluidcontainment ring 712 to an inlet 749 adjacent the first processingvolume 704. A valve may be disposed on the conduit 714 between the inlet749 and the process fluid source 716 to control delivery of processingfluid to the first processing volume 704. A first rinse fluid source 720may also be fluidly coupled to the first processing volume 704 via theconduit 714. A valve 722 may be disposed on the conduit 714 between theinlet 749 and the first rinse fluid source 720 to control delivery ofrinse fluid to the first processing volume 704. The process fluid source716 and the first rinse fluid source 720 may be similar to the processfluid source 116 and the rinse fluid source 120, respectively, which aredescribed with regard to FIG. 1.

A first drain 728 may be in fluid communication with the firstprocessing volume 704 via the conduit 714. A valve 730 may be disposedon the conduit 714 between the inlet 749 and the drain 728. Given thevertical orientation of the chamber 700, the drain 728 in fluidcommunication with the first processing volume 704 via the fluid inlet749 may provide for improved efficiency when removing process fluid orrinse fluid from the first processing volume 704. An exhaust 735 mayalso be in fluid communication with the first processing volume 704 viaa conduit 731. The conduit 731 may extend through the chamber body 702and the fluid containment ring 712 to a fluid outlet 748 adjacent thefirst processing volume 704. A valve 733 may be disposed on the conduit731 between the outlet 748 and the exhaust 735.

In operation, process fluid may be provided to the first processingvolume 704 from the process fluid source 716 and an iFGPEB process maybe performed. Any gaseous fluid in the first process volume 704 may risetoward the fluid outlet 748 as the first processing volume 704 is filledwith a liquid process fluid. Accordingly, gaseous fluids may be removedfrom the first processing volume 704 by the exhaust 735. Process fluidmay be removed from the first processing volume 704 via the fluid inlet749 and drain 728 after iFGPEB processing. Optionally, rinse fluidssupplied to the first processing volume 704 via the first rinse fluidsource 720 may be subsequently utilized with the substrate 710 in theprocessing position. Similar to the process fluids, the rinse fluids maybe removed from the first processing volume 704 via the fluid inlet 749and the drain 728.

A second rinse fluid source 778 may be in fluid communication with thesecond processing volume 754 via a conduit 774. The conduit 774 mayextend from the second rinse fluid source 778 through the sidewalls 794to an outlet 780. A valve 776 may be dispose on the conduit 774 betweenthe outlet 780 and the second rinse fluid source 778 to control deliveryof rinse fluid to the second processing volume 754. In one embodiment,after iFGPEB processing of the substrate 710 in the illustratedprocessing position, the door 706 may be moved away from the processingposition along the X-axis such that the substrate 710 is positioned in asimilar X-axis plane as the outlet 780 (i.e. a rinsing position). Oncethe substrate 710 is positioned in the rinsing position, rinse fluidfrom the second rinse fluid source 778 may be delivered to the secondprocessing volume 754 and the substrate 710. During and/or afterrinsing, the substrate 710 may be spun by the motor 772 to expel rinsefluid and other fluids/particles from the substrate 710.

A second drain 788 may also be in fluid communication with the secondprocessing volume 754. The second drain 788 may be fluidly coupled tothe second processing volume 754 via a conduit 784 which extends fromthe second drain 788 through the sidewalls 794 to an inlet 790. A valve786 may be disposed on the conduit 784 between the inlet 790 and thesecond drain 788 to control removal of fluids/particles from the secondprocessing volume 754. In operation, rinse fluids from the second rinsefluid source 778 may rinse the substrate 710 and be removed from thesecond processing volume 754 via the second drain 788.

A purge gas source 758 may also be in fluid communication with thesecond processing volume 754. The purge gas source 758 may be fluidlycoupled to the second processing volume 754 via a conduit 756 whichextends from the purge gas source 758 through the sidewalls 794 to anoutlet 782. A valve 760 may be disposed on the conduit 756 between theoutlet 782 and the purge gas source 758 to control delivery of purge gasto the second processing volume 754. In operation, purge gas may beprovided during iFGPEB processing and/or during rinsing of the substrate710 to prevent particle accumulation within the processing volumes 704,754. Purge gas from the purge gas source 758 may be removed from theprocessing volumes 704, 754 via the exhaust 735.

FIG. 8 schematically illustrates a cross-sectional view of an immersionfield guided post exposure bake chamber 800 according to one embodimentdescribed herein. The chamber 800 is similar to the chamber 700,however, the chamber 800 is oriented in a horizontal position instead ofa vertical position. A door 802, which has the first electrode 708coupled thereto, may be slidably coupled to a lift member 804. The door802 is illustrated in a processing position and may be move verticallyalong the Z-axis by the lift member 804 to a non-processing positionaway from the lid 796. In the non-processing position, the door 802 mayrotate about the X-axis 180° such that the first electrode 708 and thesubstrate 710 are disposed above the door 802 (i.e. loading position).In the loading position, the substrates may be positioned on and removedfrom the first electrode 708. In operation, the substrate 710 may besecured on the first electrode 708 when the door 802 is in the loadingposition and the door may rotate 180°. The lift member 804 may lower thedoor 802 along the Z-axis to the illustrated processing position andiFGPEB processing may be performed.

FIG. 9 illustrates operations of a method 900 for performing an iFGPEBprocess. At operation 910, a substrate may be positioned on a firstelectrode. The first electrode may be preheated prior to positioning ofthe substrate thereon. At operation 920, process fluid may be introducedto a processing volume containing the substrate. The process fluid mayalso be preheated to processing temperatures prior to introduction in tothe processing volume. A second electrode may be moved to a processingposition at operation 930. The positioning of the second electrode maybe performed prior to, during, or after introduction of the processfluid in operation 920

At operation 940, an electric field may be applied to the substrate viathe first and/or second electrodes. In one embodiment, the field may beapplied to the substrate for an amount of time between about 60 secondsand about 90 seconds. After application of the field, the process fluidmay be drained and a rinse fluid may be introduced at operation 950. Therinse fluid may be removed from the substrate by spinning the substrateand subsequently drained from the processing volume. A purge gas may beintroduced into the processing volume during or after the rinsing andspinning. The purge gas may provide for improved particle reductionafter utilization of the process fluid and the rinse fluid. The secondelectrode may also be returned to a non-processing position and thesubstrate may be removed from the processing chamber. After removal fromthe processing chamber, the substrate may be positioned on a coolingpedestal to cool the substrate to room temperature prior to subsequentprocessing.

While the foregoing is directed to embodiments of the presentdisclosure, other and further embodiments of the disclosure may bedevised without departing from the basic scope thereof, and the scopethereof is determined by the claims that follow.

What is claimed is:
 1. A substrate processing apparatus, comprising: achamber body defining a processing volume; a pedestal disposed in theprocessing volume; one or more fluid sources coupled to the processingvolume through the pedestal; a drain coupled to the processing volumethrough the pedestal; a first electrode coupled to the pedestal; a fluidcontainment ring coupled to the pedestal radially outward of the firstelectrode; a moveable stem disposed opposite the pedestal and extendingthrough the chamber body; and a second electrode coupled to the stem. 2.The apparatus of claim 1, wherein the one or more fluid sources comprisea process fluid source and a rinse fluid source.
 3. The apparatus ofclaim 1, wherein the fluid containment ring is formed from a ceramicmaterial.
 4. The apparatus of claim 1, wherein the first electrode andthe second electrode are formed from an electrically conductive metallicmaterial.
 5. The apparatus of claim 1, wherein the first electrode iscoupled to a vacuum source.
 6. The apparatus of claim 1, wherein thefirst electrode is coupled to one or more of a heat source, a powersource, a temperature sensing apparatus, and a sensing apparatus.
 7. Theapparatus of claim 6, wherein the second electrode is coupled to one ormore of a heat source, a power source, a temperature sensing apparatus,and a sensing apparatus.
 8. The apparatus of claim 1, wherein a purgegas source is coupled to the processing volume through the stem and thesecond electrode.
 9. A substrate processing apparatus, comprising: achamber body defining a processing volume; a pedestal disposed in theprocessing volume; a drain coupled to the processing volume through thepedestal; a first electrode coupled to the pedestal; a fluid containmentring coupled to the pedestal radially outward of the first electrode; amoveable stem disposed opposite the pedestal and extending through thechamber body; a second electrode coupled to the stem; a dielectriccontainment ring coupled to the second electrode; and one or more fluidsources coupled to the processing volume through the dielectriccontainment ring.
 10. The apparatus of claim 9, wherein the one or morefluid sources comprise a process fluid source and a rinse fluid source.11. The apparatus of claim 9, wherein the fluid containment ring isformed from a ceramic material.
 12. The apparatus of claim 9, whereinthe first electrode and the second electrode are formed from anelectrically conductive metallic material.
 13. The apparatus of claim 9,wherein the first electrode is coupled to a vacuum source.
 14. Theapparatus of claim 9, wherein the first electrode is coupled to one ormore of a heat source, a power source, a temperature sensing apparatus,and a sensing apparatus.
 15. The apparatus of claim 14, wherein thesecond electrode is coupled to one or more of a heat source, a powersource, a temperature sensing apparatus, and a sensing apparatus. 16.The apparatus of claim 9, wherein a purge gas source is coupled to theprocessing volume through the stem and the dielectric containment ring.